// SPDX-License-Identifier:  GPL-2.0+ OR BSD-3-Clause
/*
 * Copyright (c) 2022, Chips&Media
 * All rights reserved.
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions are met:
 *
 * 1. Redistributions of source code must retain the above copyright notice, this
 * list of conditions and the following disclaimer.
 * 2. Redistributions in binary form must reproduce the above copyright notice,
 * this list of conditions and the following disclaimer in the documentation
 * and/or other materials provided with the distribution.
 *
 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
 * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
 * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
 * ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
 * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
 * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
 * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
 * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
 *
 * Copyright (C) 2022 StarFive Technology Co., Ltd.
*/
#include <linux/kernel.h>
#include <linux/mm.h>
#include <linux/interrupt.h>
#include <linux/ioport.h>
#include <linux/module.h>
#include <linux/mutex.h>
#include <linux/platform_device.h>
#include <linux/dma-mapping.h>
#include <linux/of.h>
#include <linux/pm_runtime.h>
#include <linux/wait.h>
#include <linux/list.h>
#include <linux/clk.h>
#include <linux/delay.h>
#include <linux/uaccess.h>
#include <linux/cdev.h>
#include <linux/slab.h>
#include <linux/of_address.h>
#include <linux/sched.h>
#include <linux/sched/signal.h>
#include <linux/version.h>
#include <linux/kfifo.h>
#include <linux/kthread.h>
#include <linux/reset.h>
#include <asm/io.h>
#include "../../../vpuapi/vpuconfig.h"

#include "vpu.h"

extern void sifive_ccache_flush_range(phys_addr_t start, size_t len);

//#define ENABLE_DEBUG_MSG
#ifdef ENABLE_DEBUG_MSG
#define DPRINTK(args...)        printk(KERN_INFO args);
#else
#define DPRINTK(args...)
#endif

/* definitions to be changed as customer  configuration */
/* if you want to have clock gating scheme frame by frame */
/* #define VPU_SUPPORT_CLOCK_CONTROL */

/* if the driver want to use interrupt service from kernel ISR */
#define VPU_SUPPORT_ISR

#ifdef VPU_SUPPORT_ISR
/* if the driver want to disable and enable IRQ whenever interrupt asserted. */
//#define VPU_IRQ_CONTROL
#endif

//#define CONFIG_USE_PLL_DYNAMIC_FREQ

#define VPU_SUPPORT_CLOCK_CONTROL
/* if clktree is work,try this...*/
#define STARFIVE_VPU_SUPPORT_CLOCK_CONTROL

/* if the platform driver knows the name of this driver */
/* VPU_PLATFORM_DEVICE_NAME */
#define VPU_SUPPORT_PLATFORM_DRIVER_REGISTER

/* if this driver knows the dedicated video memory address */
//#define VPU_SUPPORT_RESERVED_VIDEO_MEMORY

#define VPU_PLATFORM_DEVICE_NAME "vdec"
#define VPU_CLK_NAME "vcodec"
#define VPU_DEV_NAME "vdec"

/* if the platform driver knows this driver */
/* the definition of VPU_REG_BASE_ADDR and VPU_REG_SIZE are not meaningful */

#define VPU_REG_BASE_ADDR 0x118F0000
#define VPU_REG_SIZE (0x4000*MAX_NUM_VPU_CORE)

#ifdef VPU_SUPPORT_ISR
#define VPU_IRQ_NUM (23)
#endif

/* this definition is only for chipsnmedia FPGA board env */
/* so for SOC env of customers can be ignored */

#ifndef VM_RESERVED /*for kernel up to 3.7.0 version*/
#define  VM_RESERVED   (VM_DONTEXPAND | VM_DONTDUMP)
#endif

struct device *vpu_dev;
typedef struct vpu_drv_context_t {
    struct fasync_struct *async_queue;
#ifdef SUPPORT_MULTI_INST_INTR
    unsigned long interrupt_reason[MAX_NUM_INSTANCE];
#else
    unsigned long interrupt_reason;
#endif
    u32 open_count;                  /*!<< device reference count. Not instance count */
} vpu_drv_context_t;

/* To track the allocated memory buffer */
typedef struct vpudrv_buffer_pool_t {
    struct list_head list;
    struct vpudrv_buffer_t vb;
    struct file *filp;
} vpudrv_buffer_pool_t;

/* To track the instance index and buffer in instance pool */
typedef struct vpudrv_instanace_list_t {
    struct list_head list;
    unsigned long inst_idx;
    unsigned long core_idx;
    struct file *filp;
} vpudrv_instanace_list_t;

typedef struct vpudrv_instance_pool_t {
    unsigned char codecInstPool[MAX_NUM_INSTANCE][MAX_INST_HANDLE_SIZE];
} vpudrv_instance_pool_t;

#ifndef STARFIVE_VPU_SUPPORT_CLOCK_CONTROL
typedef struct vpu_clkgen_t {
	void __iomem *en_ctrl;
	uint32_t rst_mask;
} vpu_clkgen_t;
#endif

struct clk_bulk_data vpu_clks[] = {
		{ .id = "apb_clk" },
		{ .id = "axi_clk" },
		{ .id = "bpu_clk" },
		{ .id = "vce_clk" },
		{ .id = "noc_bus" },
};
typedef struct vpu_clk_t {
#ifndef STARFIVE_VPU_SUPPORT_CLOCK_CONTROL
	void __iomem *clkgen;
	void __iomem *rst_ctrl;
	void __iomem *rst_status;
	void __iomem *noc_bus;
	uint32_t en_shift;
	uint32_t en_mask;
	vpu_clkgen_t apb_clk;
	vpu_clkgen_t axi_clk;
	vpu_clkgen_t bpu_clk;
	vpu_clkgen_t vce_clk;
	vpu_clkgen_t aximem_128b;
#else
	struct clk_bulk_data *clks;
	struct reset_control *resets;
	int nr_clks;
#endif
	struct device *dev;
	bool noc_ctrl;
} vpu_clk_t;

#ifdef VPU_SUPPORT_RESERVED_VIDEO_MEMORY
#include "vmm.h"
static video_mm_t s_vmem;
static vpudrv_buffer_t s_video_memory = {0};
#endif /*VPU_SUPPORT_RESERVED_VIDEO_MEMORY*/

static int vpu_hw_reset(void);
static void vpu_clk_disable(vpu_clk_t *clk);
static int vpu_clk_enable(vpu_clk_t *clk);
static vpu_clk_t *vpu_clk_get(struct platform_device *pdev);
static void vpu_clk_put(vpu_clk_t *clk);

static int vpu_pmu_enable(struct device *dev);
static void vpu_pmu_disable(struct device *dev);

/* end customer definition */
static vpudrv_buffer_t s_instance_pool = {0};
static vpudrv_buffer_t s_common_memory = {0};
static vpu_drv_context_t s_vpu_drv_context;
static dev_t s_vpu_devt;
static int s_vpu_major;
static struct cdev s_vpu_cdev;
static struct class *s_vpu_class;

static vpu_clk_t *s_vpu_clk;
static int s_vpu_open_ref_count;
#ifdef VPU_SUPPORT_ISR
static int s_vpu_irq = VPU_IRQ_NUM;
#endif

static vpudrv_buffer_t s_vpu_register = {0};

#ifdef SUPPORT_MULTI_INST_INTR
static int s_interrupt_flag[MAX_NUM_INSTANCE];
static wait_queue_head_t s_interrupt_wait_q[MAX_NUM_INSTANCE];
typedef struct kfifo kfifo_t;
static kfifo_t s_interrupt_pending_q[MAX_NUM_INSTANCE];
static spinlock_t s_kfifo_lock = __SPIN_LOCK_UNLOCKED(s_kfifo_lock);
#else
static int s_interrupt_flag;
static wait_queue_head_t s_interrupt_wait_q;
#endif

static spinlock_t s_vpu_lock = __SPIN_LOCK_UNLOCKED(s_vpu_lock);
#if LINUX_VERSION_CODE < KERNEL_VERSION(2,6,36)
static DECLARE_MUTEX(s_vpu_sem);
#else
static DEFINE_SEMAPHORE(s_vpu_sem);
#endif
static struct list_head s_vbp_head = LIST_HEAD_INIT(s_vbp_head);
static struct list_head s_inst_list_head = LIST_HEAD_INIT(s_inst_list_head);

static vpu_bit_firmware_info_t s_bit_firmware_info[MAX_NUM_VPU_CORE];

//#ifdef CONFIG_PM
/* implement to power management functions */
#define BIT_BASE                    0x0000
#define BIT_CODE_RUN                (BIT_BASE + 0x000)
#define BIT_CODE_DOWN               (BIT_BASE + 0x004)
#define BIT_INT_CLEAR               (BIT_BASE + 0x00C)
#define BIT_INT_STS                 (BIT_BASE + 0x010)
#define BIT_CODE_RESET              (BIT_BASE + 0x014)
#define BIT_INT_REASON              (BIT_BASE + 0x174)
#define BIT_BUSY_FLAG               (BIT_BASE + 0x160)
#define BIT_RUN_COMMAND             (BIT_BASE + 0x164)
#define BIT_RUN_INDEX               (BIT_BASE + 0x168)
#define BIT_RUN_COD_STD             (BIT_BASE + 0x16C)

/* WAVE5 registers */
#define W5_REG_BASE                  0x0000
#define W5_VPU_BUSY_STATUS          (W5_REG_BASE + 0x0070)
#define W5_VPU_INT_REASON_CLEAR     (W5_REG_BASE + 0x0034)
#define W5_VPU_VINT_CLEAR           (W5_REG_BASE + 0x003C)
#define W5_VPU_VPU_INT_STS          (W5_REG_BASE + 0x0044)
#define W5_VPU_INT_REASON           (W5_REG_BASE + 0x004c)
#define W5_RET_FAIL_REASON          (W5_REG_BASE + 0x010C)

#ifdef SUPPORT_MULTI_INST_INTR
#define W5_RET_BS_EMPTY_INST            (W5_REG_BASE + 0x01E4)
#define W5_RET_QUEUE_CMD_DONE_INST      (W5_REG_BASE + 0x01E8)
#define W5_RET_SEQ_DONE_INSTANCE_INFO   (W5_REG_BASE + 0x01FC)
typedef enum {
    INT_WAVE5_INIT_VPU          = 0,
    INT_WAVE5_WAKEUP_VPU        = 1,
    INT_WAVE5_SLEEP_VPU         = 2,
    INT_WAVE5_CREATE_INSTANCE   = 3,
    INT_WAVE5_FLUSH_INSTANCE    = 4,
    INT_WAVE5_DESTORY_INSTANCE  = 5,
    INT_WAVE5_INIT_SEQ          = 6,
    INT_WAVE5_SET_FRAMEBUF      = 7,
    INT_WAVE5_DEC_PIC           = 8,
    INT_WAVE5_ENC_PIC           = 8,
    INT_WAVE5_ENC_SET_PARAM     = 9,
#ifdef SUPPORT_SOURCE_RELEASE_INTERRUPT
    INT_WAVE5_ENC_SRC_RELEASE   = 10,
#endif
    INT_WAVE5_ENC_LOW_LATENCY   = 13,
    INT_WAVE5_DEC_QUERY         = 14,
    INT_WAVE5_BSBUF_EMPTY       = 15,
    INT_WAVE5_BSBUF_FULL        = 15,
} Wave5InterruptBit;
#endif

/* WAVE5 INIT, WAKEUP */
#define W5_PO_CONF                  (W5_REG_BASE + 0x0000)
#define W5_VPU_VINT_ENABLE          (W5_REG_BASE + 0x0048)

#define W5_VPU_RESET_REQ            (W5_REG_BASE + 0x0050)
#define W5_VPU_RESET_STATUS         (W5_REG_BASE + 0x0054)

#define W5_VPU_REMAP_CTRL           (W5_REG_BASE + 0x0060)
#define W5_VPU_REMAP_VADDR          (W5_REG_BASE + 0x0064)
#define W5_VPU_REMAP_PADDR          (W5_REG_BASE + 0x0068)
#define W5_VPU_REMAP_CORE_START     (W5_REG_BASE + 0x006C)

#define W5_REMAP_CODE_INDEX          0


/* WAVE5 registers */
#define W5_ADDR_CODE_BASE               (W5_REG_BASE + 0x0110)
#define W5_CODE_SIZE                    (W5_REG_BASE + 0x0114)
#define W5_CODE_PARAM                   (W5_REG_BASE + 0x0118)
#define W5_INIT_VPU_TIME_OUT_CNT        (W5_REG_BASE + 0x0130)

#define W5_HW_OPTION                    (W5_REG_BASE + 0x012C)

#define W5_RET_SUCCESS                  (W5_REG_BASE + 0x0108)


#define W5_COMMAND                      (W5_REG_BASE + 0x0100)
#define W5_VPU_HOST_INT_REQ             (W5_REG_BASE + 0x0038)

/* Product register */
#define VPU_PRODUCT_CODE_REGISTER       (BIT_BASE + 0x1044)
#if defined(VPU_SUPPORT_PLATFORM_DRIVER_REGISTER) && defined(CONFIG_PM)
static u32  s_vpu_reg_store[MAX_NUM_VPU_CORE][64];
#endif
//#endif //CONFIG_PM

#define ReadVpuRegister(addr)       *(volatile unsigned int *)(s_vpu_register.virt_addr + s_bit_firmware_info[core].reg_base_offset + addr)
#define WriteVpuRegister(addr, val) *(volatile unsigned int *)(s_vpu_register.virt_addr + s_bit_firmware_info[core].reg_base_offset + addr) = (unsigned int)val
#define WriteVpu(addr, val)         *(volatile unsigned int *)(addr) = (unsigned int)val;

#if defined(CONFIG_CPU_FREQ) && defined(CONFIG_USE_PLL_DYNAMIC_FREQ)
#include <linux/fs.h>
#include <linux/file.h>

struct freq_ctrl {
	struct device *dev;
	struct file *governor;
	struct file *maxfreq;
	struct file *parameters_off;
	const char *scaling_governor;
	const char *scaling_maxfreq;
	const char *scaling_parameters_off;
	const char *fixed_freq;
	char re_cpu_gov[16];
	char re_max_freq[16];
	struct mutex mutex_lock;
	int count;
};

static struct freq_ctrl *vpu_freq_ctrl;

static int vpu_freq_open(struct freq_ctrl *vpu_freq_ctrl)
{
	vpu_freq_ctrl->governor = filp_open(
				vpu_freq_ctrl->scaling_governor, O_RDWR, 0);
	if (IS_ERR(vpu_freq_ctrl->governor))
		goto out;

	vpu_freq_ctrl->maxfreq = filp_open(
				vpu_freq_ctrl->scaling_maxfreq, O_RDWR, 0);
	if (IS_ERR(vpu_freq_ctrl->maxfreq))
		goto out;

	vpu_freq_ctrl->parameters_off = filp_open(
				vpu_freq_ctrl->scaling_parameters_off, O_RDWR, 0);
	if (IS_ERR(vpu_freq_ctrl->parameters_off))
		goto out;

	return 0;
out:
	dev_err(vpu_freq_ctrl->dev, "failed open scaling_governor.\n");
	return -ENXIO;
}

static int vpu_freq_close(void)
{
	if (!vpu_freq_ctrl)
		return -ENODEV;

	mutex_destroy(&vpu_freq_ctrl->mutex_lock);

	if (vpu_freq_ctrl->governor && vpu_freq_ctrl->maxfreq
		&& vpu_freq_ctrl->parameters_off) {
		fput(vpu_freq_ctrl->governor);
		fput(vpu_freq_ctrl->maxfreq);
		fput(vpu_freq_ctrl->parameters_off);
		vpu_freq_ctrl->governor = NULL;
		vpu_freq_ctrl->maxfreq = NULL;
		vpu_freq_ctrl->parameters_off = NULL;
	}
	return 0;
}

static int vpu_freq_save_env(void)
{
	const char *fixed_freq = vpu_freq_ctrl->fixed_freq;
	const char *governor_mode = "performance";
	size_t rv;

	if (!vpu_freq_ctrl)
		return -ENODEV;

	mutex_lock(&vpu_freq_ctrl->mutex_lock);

	if (vpu_freq_ctrl->count == 0) {
		/*save env*/
		kernel_read(vpu_freq_ctrl->governor, vpu_freq_ctrl->re_cpu_gov,
				sizeof(vpu_freq_ctrl->re_cpu_gov), NULL);
		kernel_read(vpu_freq_ctrl->maxfreq, vpu_freq_ctrl->re_max_freq,
				sizeof(vpu_freq_ctrl->re_max_freq), NULL);

		/*setenv*/
		rv = kernel_write(vpu_freq_ctrl->maxfreq, fixed_freq,
				strlen(fixed_freq), NULL);
		rv = kernel_write(vpu_freq_ctrl->governor, governor_mode,
				strlen(governor_mode), NULL);
		rv = kernel_write(vpu_freq_ctrl->parameters_off, "1", 1, NULL);
	}
	vpu_freq_ctrl->count++;

	mutex_unlock(&vpu_freq_ctrl->mutex_lock);

	return 0;
}

static int vpu_freq_put_env(void)
{
	size_t rv;

	if (!vpu_freq_ctrl)
		return -ENODEV;

	mutex_lock(&vpu_freq_ctrl->mutex_lock);

	vpu_freq_ctrl->count--;

	if (vpu_freq_ctrl->count == 0) {
		rv = kernel_write(vpu_freq_ctrl->governor, vpu_freq_ctrl->re_cpu_gov,
				strlen(vpu_freq_ctrl->re_cpu_gov), NULL);
		rv = kernel_write(vpu_freq_ctrl->maxfreq, vpu_freq_ctrl->re_max_freq,
				strlen(vpu_freq_ctrl->re_max_freq), NULL);
		rv = kernel_write(vpu_freq_ctrl->parameters_off, "0", 1, NULL);
	}

	mutex_unlock(&vpu_freq_ctrl->mutex_lock);
	return 0;
}

static int vpu_freq_init(struct device *dev)
{
	int ret;
	const char *of_str;

	vpu_freq_ctrl = devm_kzalloc(dev, sizeof(*vpu_freq_ctrl), GFP_KERNEL);
	if (!vpu_freq_ctrl)
		return -ENOMEM;

	vpu_freq_ctrl->scaling_governor = "/sys/devices/system/cpu/cpufreq/policy0/scaling_governor";
	vpu_freq_ctrl->scaling_maxfreq = "/sys/devices/system/cpu/cpufreq/policy0/scaling_max_freq";
	vpu_freq_ctrl->scaling_parameters_off = "/sys/module/cpufreq/parameters/off";
	vpu_freq_ctrl->dev = dev;

	ret = vpu_freq_open(vpu_freq_ctrl);
	if (ret) {
		devm_kfree(dev, vpu_freq_ctrl);
		vpu_freq_ctrl = NULL;
		return ret;
	}

	if (!device_property_read_string(dev, "vdec,runtime-cpufreq", &of_str))
		vpu_freq_ctrl->fixed_freq = of_str;
	else
		vpu_freq_ctrl->fixed_freq = "1250000";

	vpu_freq_ctrl->count = 0;
	mutex_init(&vpu_freq_ctrl->mutex_lock);

	dev_dbg(dev, "fixed_freq:%s\n", vpu_freq_ctrl->fixed_freq);

	return 0;
}

#endif

static void starfive_flush_dcache(phys_addr_t start, size_t len)
{
#ifdef ARCH_HAS_SYNC_DMA_FOR_DEVICE
	dma_sync_single_for_device(vpu_dev, start, len, DMA_FROM_DEVICE);
#else
	sifive_ccache_flush_range(start, len);
#endif
}

static int vpu_alloc_dma_buffer(vpudrv_buffer_t *vb)
{
    if (!vb)
        return -1;

    DPRINTK("[VPUDRV] vpu_alloc_dma_buffer \n");
#ifdef VPU_SUPPORT_RESERVED_VIDEO_MEMORY
    vb->phys_addr = (unsigned long)vmem_alloc(&s_vmem, vb->size, 0);
    if ((unsigned long)vb->phys_addr  == (unsigned long)-1) {
        printk(KERN_ERR "[VPUDRV] Physical memory allocation error size=%d\n", vb->size);
        return -1;
    }

    vb->base = (unsigned long)(s_video_memory.base + (vb->phys_addr - s_video_memory.phys_addr));
#else

	vb->base = (unsigned long)dma_alloc_coherent(vpu_dev, PAGE_ALIGN(vb->size), (dma_addr_t *) (&vb->phys_addr), GFP_DMA | GFP_KERNEL);
	if ((void *)(vb->base) == NULL)	{
		printk(KERN_ERR "[VPUDRV] Physical memory allocation error size=%d\n", vb->size);
		return -1;
	}
	starfive_flush_dcache(vb->phys_addr,PAGE_ALIGN(vb->size));
#endif
    return 0;
}


static void vpu_free_dma_buffer(vpudrv_buffer_t *vb)
{
    if (!vb)
        return;

#ifdef VPU_SUPPORT_RESERVED_VIDEO_MEMORY
    if (vb->base)
        vmem_free(&s_vmem, vb->phys_addr, 0);
#else
    if (vb->base)
		dma_free_coherent(vpu_dev, PAGE_ALIGN(vb->size), (void *)vb->base, vb->phys_addr);
#endif
}

static int vpu_free_instances(struct file *filp)
{
    vpudrv_instanace_list_t *vil, *n;
    vpudrv_instance_pool_t *vip;
    void *vip_base;
    int instance_pool_size_per_core;

#if !defined(PTHREAD_MUTEX_ROBUST_NP)
    void *vdi_mutexes_base;
    const int PTHREAD_MUTEX_T_DESTROY_VALUE = 0xdead10cc;
#endif

    DPRINTK("[VPUDRV] vpu_free_instances\n");

    instance_pool_size_per_core = (s_instance_pool.size/MAX_NUM_VPU_CORE); /* s_instance_pool.size  assigned to the size of all core once call VDI_IOCTL_GET_INSTANCE_POOL by user. */

    list_for_each_entry_safe(vil, n, &s_inst_list_head, list)
    {
        if (vil->filp == filp) {
            vip_base = (void *)(s_instance_pool.base + (instance_pool_size_per_core*vil->core_idx));
            DPRINTK("[VPUDRV] vpu_free_instances detect instance crash instIdx=%d, coreIdx=%d, vip_base=%p, instance_pool_size_per_core=%d\n", (int)vil->inst_idx, (int)vil->core_idx, vip_base, (int)instance_pool_size_per_core);
            vip = (vpudrv_instance_pool_t *)vip_base;
            if (vip) {
                memset(&vip->codecInstPool[vil->inst_idx], 0x00, 4);    /* only first 4 byte is key point(inUse of CodecInst in vpuapi) to free the corresponding instance. */
#if !defined(PTHREAD_MUTEX_ROBUST_NP)
#define PTHREAD_MUTEX_T_HANDLE_SIZE 4
                vdi_mutexes_base = (vip_base + (instance_pool_size_per_core - PTHREAD_MUTEX_T_HANDLE_SIZE*4));
                DPRINTK("[VPUDRV] vpu_free_instances : force to destroy vdi_mutexes_base=%p in userspace \n", vdi_mutexes_base);
                if (vdi_mutexes_base) {
                    int i;
                    for (i = 0; i < 4; i++) {
                        memcpy(vdi_mutexes_base, &PTHREAD_MUTEX_T_DESTROY_VALUE, PTHREAD_MUTEX_T_HANDLE_SIZE);
                        vdi_mutexes_base += PTHREAD_MUTEX_T_HANDLE_SIZE;
                    }
                }
#endif
            }
            s_vpu_open_ref_count--;
            list_del(&vil->list);
            kfree(vil);
        }
    }
    return 1;
}

static int vpu_free_buffers(struct file *filp)
{
    vpudrv_buffer_pool_t *pool, *n;
    vpudrv_buffer_t vb;

    DPRINTK("[VPUDRV] vpu_free_buffers\n");

    list_for_each_entry_safe(pool, n, &s_vbp_head, list)
    {
        if (pool->filp == filp) {
            vb = pool->vb;
            if (vb.base) {
                vpu_free_dma_buffer(&vb);
                list_del(&pool->list);
                kfree(pool);
            }
        }
    }

    return 0;
}

#ifdef SUPPORT_MULTI_INST_INTR
static inline u32 get_inst_idx(u32 reg_val)
{
    u32 inst_idx;
    int i;
    for (i=0; i < MAX_NUM_INSTANCE; i++)
    {
        if(((reg_val >> i)&0x01) == 1)
            break;
    }
    inst_idx = i;
    return inst_idx;
}

static s32 get_vpu_inst_idx(vpu_drv_context_t *dev, u32 *reason, u32 empty_inst, u32 done_inst, u32 seq_inst)
{
    s32 inst_idx;
    u32 reg_val;
    u32 int_reason;

    int_reason = *reason;
    DPRINTK("[VPUDRV][+]%s, int_reason=0x%x, empty_inst=0x%x, done_inst=0x%x\n", __func__, int_reason, empty_inst, done_inst);
    //printk(KERN_ERR "[VPUDRV][+]%s, int_reason=0x%x, empty_inst=0x%x, done_inst=0x%x\n", __func__, int_reason, empty_inst, done_inst);

    if (int_reason & (1 << INT_WAVE5_BSBUF_EMPTY))
    {
        reg_val = (empty_inst & 0xffff);
        inst_idx = get_inst_idx(reg_val);
        *reason = (1 << INT_WAVE5_BSBUF_EMPTY);
        DPRINTK("[VPUDRV]   %s, W5_RET_BS_EMPTY_INST reg_val=0x%x, inst_idx=%d\n", __func__, reg_val, inst_idx);
        goto GET_VPU_INST_IDX_HANDLED;
    }

    if (int_reason & (1 << INT_WAVE5_INIT_SEQ))
    {
        reg_val = (seq_inst & 0xffff);
        inst_idx = get_inst_idx(reg_val);
        *reason  = (1 << INT_WAVE5_INIT_SEQ);
        DPRINTK("[VPUDRV]   %s, RET_SEQ_DONE_INSTANCE_INFO INIT_SEQ reg_val=0x%x, inst_idx=%d\n", __func__, reg_val, inst_idx);
        goto GET_VPU_INST_IDX_HANDLED;
    }

    if (int_reason & (1 << INT_WAVE5_DEC_PIC))
    {
        reg_val = (done_inst & 0xffff);
        inst_idx = get_inst_idx(reg_val);
        *reason  = (1 << INT_WAVE5_DEC_PIC);
        DPRINTK("[VPUDRV]   %s, W5_RET_QUEUE_CMD_DONE_INST DEC_PIC reg_val=0x%x, inst_idx=%d\n", __func__, reg_val, inst_idx);

        if (int_reason & (1 << INT_WAVE5_ENC_LOW_LATENCY))
        {
            u32 ll_inst_idx;
            reg_val = (done_inst >> 16);
            ll_inst_idx = get_inst_idx(reg_val);
            if (ll_inst_idx == inst_idx)
                *reason = ((1 << INT_WAVE5_DEC_PIC) | (1 << INT_WAVE5_ENC_LOW_LATENCY));
            DPRINTK("[VPUDRV]   %s, W5_RET_QUEUE_CMD_DONE_INST DEC_PIC and ENC_LOW_LATENCY reg_val=0x%x, inst_idx=%d, ll_inst_idx=%d\n", __func__, reg_val, inst_idx, ll_inst_idx);
        }
        goto GET_VPU_INST_IDX_HANDLED;
    }

    if (int_reason & (1 << INT_WAVE5_ENC_SET_PARAM))
    {
        reg_val = (seq_inst & 0xffff);
        inst_idx = get_inst_idx(reg_val);
        *reason  = (1 << INT_WAVE5_ENC_SET_PARAM);
        DPRINTK("[VPUDRV]   %s, RET_SEQ_DONE_INSTANCE_INFO ENC_SET_PARAM reg_val=0x%x, inst_idx=%d\n", __func__, reg_val, inst_idx);
        goto GET_VPU_INST_IDX_HANDLED;
    }

#ifdef SUPPORT_SOURCE_RELEASE_INTERRUPT
    if (int_reason & (1 << INT_WAVE5_ENC_SRC_RELEASE))
    {
        reg_val = (done_inst & 0xffff);
        inst_idx = get_inst_idx(reg_val);
        *reason  = (1 << INT_WAVE5_ENC_SRC_RELEASE);
        DPRINTK("[VPUDRV]   %s, W5_RET_QUEUE_CMD_DONE_INST ENC_SET_PARAM reg_val=0x%x, inst_idx=%d\n", __func__, reg_val, inst_idx);
        goto GET_VPU_INST_IDX_HANDLED;
    }
#endif

    if (int_reason & (1 << INT_WAVE5_ENC_LOW_LATENCY))
    {
        reg_val = (done_inst >> 16);
        inst_idx = get_inst_idx(reg_val);
        *reason  = (1 << INT_WAVE5_ENC_LOW_LATENCY);
        DPRINTK("[VPUDRV]   %s, W5_RET_QUEUE_CMD_DONE_INST ENC_LOW_LATENCY reg_val=0x%x, inst_idx=%d\n", __func__, reg_val, inst_idx);
        goto GET_VPU_INST_IDX_HANDLED;
    }

    inst_idx = -1;
    *reason  = 0;
    DPRINTK("[VPUDRV]   %s, UNKNOWN INTERRUPT REASON: %08x\n", __func__, int_reason);

GET_VPU_INST_IDX_HANDLED:

    DPRINTK("[VPUDRV][-]%s, inst_idx=%d. *reason=0x%x\n", __func__, inst_idx, *reason);

    return inst_idx;
}
#endif

static irqreturn_t vpu_irq_handler(int irq, void *dev_id)
{
    vpu_drv_context_t *dev = (vpu_drv_context_t *)dev_id;

    /* this can be removed. it also work in VPU_WaitInterrupt of API function */
    int core;
    int product_code;
#ifdef SUPPORT_MULTI_INST_INTR
    u32 intr_reason;
    s32 intr_inst_index;
#endif
    DPRINTK("[VPUDRV][+]%s\n", __func__);

#ifdef VPU_IRQ_CONTROL
    disable_irq_nosync(s_vpu_irq);
#endif

#ifdef SUPPORT_MULTI_INST_INTR
    intr_inst_index = 0;
    intr_reason = 0;
#endif
    for (core = 0; core < MAX_NUM_VPU_CORE; core++) {
        if (s_bit_firmware_info[core].size == 0) {/* it means that we didn't get an information the current core from API layer. No core activated.*/
            printk(KERN_ERR "[VPUDRV] :  s_bit_firmware_info[core].size is zero\n");
            continue;
        }
        product_code = ReadVpuRegister(VPU_PRODUCT_CODE_REGISTER);

        if (PRODUCT_CODE_W_SERIES(product_code)) {
            if (ReadVpuRegister(W5_VPU_VPU_INT_STS)) {
#ifdef SUPPORT_MULTI_INST_INTR
                u32 empty_inst;
                u32 done_inst;
                u32 seq_inst;
                u32 i, reason, reason_clr;

                reason      = ReadVpuRegister(W5_VPU_INT_REASON);
                empty_inst = ReadVpuRegister(W5_RET_BS_EMPTY_INST);
                done_inst = ReadVpuRegister(W5_RET_QUEUE_CMD_DONE_INST);
                seq_inst    = ReadVpuRegister(W5_RET_SEQ_DONE_INSTANCE_INFO);
                reason_clr  = reason;

                DPRINTK("[VPUDRV] vpu_irq_handler reason=0x%x, empty_inst=0x%x, done_inst=0x%x, seq_inst=0x%x \n", reason, empty_inst, done_inst, seq_inst);
                for (i=0; i<MAX_NUM_INSTANCE; i++) {
                    if (0 == empty_inst && 0 == done_inst && 0 == seq_inst) break;
                    intr_reason = reason;
                    intr_inst_index = get_vpu_inst_idx(dev, &intr_reason, empty_inst, done_inst, seq_inst);
                    DPRINTK("[VPUDRV]     > instance_index: %d, intr_reason: %08x empty_inst: %08x done_inst: %08x seq_inst: %08x\n", intr_inst_index, intr_reason, empty_inst, done_inst, seq_inst);
                    if (intr_inst_index >= 0 && intr_inst_index < MAX_NUM_INSTANCE) {
                        if (intr_reason == (1 << INT_WAVE5_BSBUF_EMPTY)) {
                            empty_inst = empty_inst & ~(1 << intr_inst_index);
                            WriteVpuRegister(W5_RET_BS_EMPTY_INST, empty_inst);
                            if (0 == empty_inst) {
                                reason &= ~(1<<INT_WAVE5_BSBUF_EMPTY);
                            }
                            DPRINTK("[VPUDRV]   %s, W5_RET_BS_EMPTY_INST Clear empty_inst=0x%x, intr_inst_index=%d\n", __func__, empty_inst, intr_inst_index);
                        }
                        if (intr_reason == (1 << INT_WAVE5_DEC_PIC))
                        {
                            done_inst = done_inst & ~(1 << intr_inst_index);
                            WriteVpuRegister(W5_RET_QUEUE_CMD_DONE_INST, done_inst);
                            if (0 == done_inst) {
                                reason &= ~(1<<INT_WAVE5_DEC_PIC);
                            }
                            DPRINTK("[VPUDRV]   %s, W5_RET_QUEUE_CMD_DONE_INST Clear done_inst=0x%x, intr_inst_index=%d\n", __func__, done_inst, intr_inst_index);
                        }
                        if ((intr_reason == (1 << INT_WAVE5_INIT_SEQ)) || (intr_reason == (1 << INT_WAVE5_ENC_SET_PARAM)))
                        {
                            seq_inst = seq_inst & ~(1 << intr_inst_index);
                            WriteVpuRegister(W5_RET_SEQ_DONE_INSTANCE_INFO, seq_inst);
                            if (0 == seq_inst) {
                                reason &= ~(1<<INT_WAVE5_INIT_SEQ | 1<<INT_WAVE5_ENC_SET_PARAM);
                            }
                            DPRINTK("[VPUDRV]   %s, W5_RET_SEQ_DONE_INSTANCE_INFO Clear done_inst=0x%x, intr_inst_index=%d\n", __func__, done_inst, intr_inst_index);
                        }
                        if ((intr_reason == (1 << INT_WAVE5_ENC_LOW_LATENCY)))
                        {
                            done_inst = (done_inst >> 16);
                            done_inst = done_inst & ~(1 << intr_inst_index);
                            done_inst = (done_inst << 16);
                            WriteVpuRegister(W5_RET_QUEUE_CMD_DONE_INST, done_inst);
                            if (0 == done_inst) {
                                reason &= ~(1 << INT_WAVE5_ENC_LOW_LATENCY);
                            }
                            DPRINTK("[VPUDRV]   %s, W5_RET_QUEUE_CMD_DONE_INST INT_WAVE5_ENC_LOW_LATENCY Clear done_inst=0x%x, intr_inst_index=%d\n", __func__, done_inst, intr_inst_index);
                        }
                        if (!kfifo_is_full(&s_interrupt_pending_q[intr_inst_index])) {
                            if (intr_reason == ((1 << INT_WAVE5_ENC_PIC) | (1 << INT_WAVE5_ENC_LOW_LATENCY))) {
                                u32 ll_intr_reason = (1 << INT_WAVE5_ENC_PIC);
                                kfifo_in_spinlocked(&s_interrupt_pending_q[intr_inst_index], &ll_intr_reason, sizeof(u32), &s_kfifo_lock);
                            }
                            else
                                kfifo_in_spinlocked(&s_interrupt_pending_q[intr_inst_index], &intr_reason, sizeof(u32), &s_kfifo_lock);
                        }
                        else {
                            printk(KERN_ERR "[VPUDRV] :  kfifo_is_full kfifo_count=%d \n", kfifo_len(&s_interrupt_pending_q[intr_inst_index]));
                        }
                    }
                    else {
                        printk(KERN_ERR "[VPUDRV] :  intr_inst_index is wrong intr_inst_index=%d \n", intr_inst_index);
                    }
                }

                if (0 != reason)
                    printk(KERN_ERR "INTERRUPT REASON REMAINED: %08x\n", reason);
                WriteVpuRegister(W5_VPU_INT_REASON_CLEAR, reason_clr);
#else
                dev->interrupt_reason = ReadVpuRegister(W5_VPU_INT_REASON);
                WriteVpuRegister(W5_VPU_INT_REASON_CLEAR, dev->interrupt_reason);
#endif

                WriteVpuRegister(W5_VPU_VINT_CLEAR, 0x1);
            }
        }
        else if (PRODUCT_CODE_NOT_W_SERIES(product_code)) {
            if (ReadVpuRegister(BIT_INT_STS)) {
#ifdef SUPPORT_MULTI_INST_INTR
                intr_reason = ReadVpuRegister(BIT_INT_REASON);
                intr_inst_index = 0; // in case of coda seriese. treats intr_inst_index is already 0
                kfifo_in_spinlocked(&s_interrupt_pending_q[intr_inst_index], &intr_reason, sizeof(u32), &s_kfifo_lock);
#else
                dev->interrupt_reason = ReadVpuRegister(BIT_INT_REASON);
#endif
                WriteVpuRegister(BIT_INT_CLEAR, 0x1);
            }
        }
        else {
            DPRINTK("[VPUDRV] Unknown product id : %08x\n", product_code);
            continue;
        }
#ifdef SUPPORT_MULTI_INST_INTR
        DPRINTK("[VPUDRV] product: 0x%08x intr_reason: 0x%08x\n\n", product_code, intr_reason);
#else
        DPRINTK("[VPUDRV] product: 0x%08x intr_reason: 0x%08x\n", product_code, dev->interrupt_reason);
#endif
    }

    if (dev->async_queue)
        kill_fasync(&dev->async_queue, SIGIO, POLL_IN); /* notify the interrupt to user space */

#ifdef SUPPORT_MULTI_INST_INTR
    if (intr_inst_index >= 0 && intr_inst_index < MAX_NUM_INSTANCE) {
        s_interrupt_flag[intr_inst_index]= 1;
        wake_up_interruptible(&s_interrupt_wait_q[intr_inst_index]);
    }
#else
    s_interrupt_flag = 1;

    wake_up_interruptible(&s_interrupt_wait_q);
#endif
    DPRINTK("[VPUDRV][-]%s\n", __func__);

    return IRQ_HANDLED;
}

static int vpu_open(struct inode *inode, struct file *filp)
{
    DPRINTK("[VPUDRV][+] %s\n", __func__);
    pm_runtime_get_sync(s_vpu_clk->dev);
    spin_lock(&s_vpu_lock);

    s_vpu_drv_context.open_count++;

    filp->private_data = (void *)(&s_vpu_drv_context);
    spin_unlock(&s_vpu_lock);

    DPRINTK("[VPUDRV][-] %s\n", __func__);

    return 0;
}

/*static int vpu_ioctl(struct inode *inode, struct file *filp, u_int cmd, u_long arg) // for kernel 2.6.9 of C&M*/
static long vpu_ioctl(struct file *filp, u_int cmd, u_long arg)
{
    int ret = 0;
    struct vpu_drv_context_t *dev = (struct vpu_drv_context_t *)filp->private_data;

    switch (cmd) {
    case VDI_IOCTL_GET_PHYSICAL_MEMORY:
        {
            vpudrv_buffer_pool_t *vbp = NULL;
            void *user_address = NULL;
            struct task_struct *my_struct = NULL;
            struct mm_struct *mm = NULL;
            unsigned long address = 0;
            pgd_t *pgd = NULL;
            if ((ret = down_interruptible(&s_vpu_sem)) == 0) {
                vbp = kzalloc(sizeof(*vbp), GFP_KERNEL);
                if (!vbp) {
                    up(&s_vpu_sem);
                    return -ENOMEM;
                }
                ret = copy_from_user(&(vbp->vb), (vpudrv_buffer_t *)arg, sizeof(vpudrv_buffer_t));
                if (ret) {
                    kfree(vbp);
                    up(&s_vpu_sem);
                    return -EFAULT;
                }

                user_address = (void *)vbp->vb.virt_addr;
                my_struct = get_current();
                mm = my_struct->mm;
                address = (unsigned long)user_address;
                pgd = pgd_offset(mm, address);

                if (!pgd_none(*pgd) && !pgd_bad(*pgd)) {
                    p4d_t *p4d = p4d_offset(pgd, address);
                    pud_t *pud = pud_offset(p4d, address);
                    if (!pud_none(*pud) && !pud_bad(*pud)) {
                        pmd_t *pmd = pmd_offset(pud, address);
                        if (!pmd_none(*pmd) && !pmd_bad(*pmd)) {
                            pte_t *pte = pte_offset_map(pmd, address);
                            if (!pte_none(*pte)) {
                                struct page *pg = pte_page(*pte);
                                unsigned long phys = page_to_phys(pg);
                                unsigned long virt = (unsigned long)phys_to_virt(phys);
                                printk("attach phy address = %lx, virt = %lx\r\n", phys, virt);
                                vbp->vb.phys_addr = phys;
                                vbp->vb.base = virt;
                            }
                            pte_unmap(pte);
                        }
                    }
                }
                ret = copy_to_user((void __user *)arg, &(vbp->vb), sizeof(vpudrv_buffer_t));
                if (ret) {
                    kfree(vbp);
                    ret = -EFAULT;
                    up(&s_vpu_sem);
                    break;
                }
                vbp->filp = filp;
                spin_lock(&s_vpu_lock);
                list_add(&vbp->list, &s_vbp_head);
                spin_unlock(&s_vpu_lock);
                up(&s_vpu_sem);
            }
        }
        break;
    case VDI_IOCTL_ALLOCATE_PHYSICAL_MEMORY:
        {
            vpudrv_buffer_pool_t *vbp;

            DPRINTK("[VPUDRV][+]VDI_IOCTL_ALLOCATE_PHYSICAL_MEMORY\n");

            if ((ret = down_interruptible(&s_vpu_sem)) == 0) {
                vbp = kzalloc(sizeof(*vbp), GFP_KERNEL);
                if (!vbp) {
                    up(&s_vpu_sem);
                    return -ENOMEM;
                }

                ret = copy_from_user(&(vbp->vb), (vpudrv_buffer_t *)arg, sizeof(vpudrv_buffer_t));
                if (ret) {
                    kfree(vbp);
                    up(&s_vpu_sem);
                    return -EFAULT;
                }

                ret = vpu_alloc_dma_buffer(&(vbp->vb));
                if (ret == -1) {
                    ret = -ENOMEM;
                    kfree(vbp);
                    up(&s_vpu_sem);
                    break;
                }
                ret = copy_to_user((void __user *)arg, &(vbp->vb), sizeof(vpudrv_buffer_t));
                if (ret) {
                    kfree(vbp);
                    ret = -EFAULT;
                    up(&s_vpu_sem);
                    break;
                }

                vbp->filp = filp;
                spin_lock(&s_vpu_lock);
                list_add(&vbp->list, &s_vbp_head);
                spin_unlock(&s_vpu_lock);

                up(&s_vpu_sem);
            }
            DPRINTK("[VPUDRV][-]VDI_IOCTL_ALLOCATE_PHYSICAL_MEMORY\n");
        }
        break;
    case VDI_IOCTL_FREE_PHYSICALMEMORY:
        {
            vpudrv_buffer_pool_t *vbp, *n;
            vpudrv_buffer_t vb;
            DPRINTK("[VPUDRV][+]VDI_IOCTL_FREE_PHYSICALMEMORY\n");

            if ((ret = down_interruptible(&s_vpu_sem)) == 0) {

                ret = copy_from_user(&vb, (vpudrv_buffer_t *)arg, sizeof(vpudrv_buffer_t));
                if (ret) {
                    up(&s_vpu_sem);
                    return -EACCES;
                }

                if (vb.base)
                    vpu_free_dma_buffer(&vb);

                spin_lock(&s_vpu_lock);
                list_for_each_entry_safe(vbp, n, &s_vbp_head, list)
                {
                    if (vbp->vb.base == vb.base) {
                        list_del(&vbp->list);
                        kfree(vbp);
                        break;
                    }
                }
                spin_unlock(&s_vpu_lock);

                up(&s_vpu_sem);
            }
            DPRINTK("[VPUDRV][-]VDI_IOCTL_FREE_PHYSICALMEMORY\n");

        }
        break;
    case VDI_IOCTL_GET_RESERVED_VIDEO_MEMORY_INFO:
        {
#ifdef VPU_SUPPORT_RESERVED_VIDEO_MEMORY
            DPRINTK("[VPUDRV][+]VDI_IOCTL_GET_RESERVED_VIDEO_MEMORY_INFO\n");
            if (s_video_memory.base != 0) {
                ret = copy_to_user((void __user *)arg, &s_video_memory, sizeof(vpudrv_buffer_t));
                if (ret != 0)
                    ret = -EFAULT;
            } else {
                ret = -EFAULT;
            }
            DPRINTK("[VPUDRV][-]VDI_IOCTL_GET_RESERVED_VIDEO_MEMORY_INFO\n");
#endif
        }
        break;

    case VDI_IOCTL_WAIT_INTERRUPT:
        {
            vpudrv_intr_info_t info;
#ifdef SUPPORT_MULTI_INST_INTR
            u32 intr_inst_index;
            u32 intr_reason_in_q;
            u32 interrupt_flag_in_q;
#endif
            DPRINTK("[VPUDRV][+]VDI_IOCTL_WAIT_INTERRUPT\n");


            ret = copy_from_user(&info, (vpudrv_intr_info_t *)arg, sizeof(vpudrv_intr_info_t));
            if (ret != 0)
            {
                return -EFAULT;
            }

#ifdef SUPPORT_MULTI_INST_INTR
            intr_inst_index = info.intr_inst_index;

            intr_reason_in_q = 0;
            interrupt_flag_in_q = kfifo_out_spinlocked(&s_interrupt_pending_q[intr_inst_index], &intr_reason_in_q, sizeof(u32), &s_kfifo_lock);
            if (interrupt_flag_in_q > 0)
            {
                dev->interrupt_reason[intr_inst_index] = intr_reason_in_q;
                DPRINTK("[VPUDRV] Interrupt Remain : intr_inst_index=%d, intr_reason_in_q=0x%x, interrupt_flag_in_q=%d\n", intr_inst_index, intr_reason_in_q, interrupt_flag_in_q);
                goto INTERRUPT_REMAIN_IN_QUEUE;
            }
#endif
#ifdef SUPPORT_MULTI_INST_INTR
#ifdef SUPPORT_TIMEOUT_RESOLUTION
            kt =  ktime_set(0, info.timeout*1000*1000);
            ret = wait_event_interruptible_hrtimeout(s_interrupt_wait_q[intr_inst_index], s_interrupt_flag[intr_inst_index] != 0, kt);
#else
            ret = wait_event_interruptible_timeout(s_interrupt_wait_q[intr_inst_index], s_interrupt_flag[intr_inst_index] != 0, msecs_to_jiffies(info.timeout));
#endif
#else
            ret = wait_event_interruptible_timeout(s_interrupt_wait_q, s_interrupt_flag != 0, msecs_to_jiffies(info.timeout));
#endif
#ifdef SUPPORT_TIMEOUT_RESOLUTION
            if (ret == -ETIME) {
                //DPRINTK("[VPUDRV][-]VDI_IOCTL_WAIT_INTERRUPT timeout = %d \n", info.timeout);
                break;
            }
#endif
            if (!ret) {
                ret = -ETIME;
                break;
            }

            if (signal_pending(current)) {
                ret = -ERESTARTSYS;
                break;
            }

#ifdef SUPPORT_MULTI_INST_INTR
            intr_reason_in_q = 0;
            interrupt_flag_in_q = kfifo_out_spinlocked(&s_interrupt_pending_q[intr_inst_index], &intr_reason_in_q, sizeof(u32), &s_kfifo_lock);
            if (interrupt_flag_in_q > 0) {
                dev->interrupt_reason[intr_inst_index] = intr_reason_in_q;
            }
            else {
                dev->interrupt_reason[intr_inst_index] = 0;
            }
#endif
#ifdef SUPPORT_MULTI_INST_INTR
            DPRINTK("[VPUDRV] inst_index(%d), s_interrupt_flag(%d), reason(0x%08lx)\n", intr_inst_index, s_interrupt_flag[intr_inst_index], dev->interrupt_reason[intr_inst_index]);
#else
            DPRINTK("[VPUDRV]   s_interrupt_flag(%d), reason(0x%08lx)\n", s_interrupt_flag, dev->interrupt_reason);
#endif

#ifdef SUPPORT_MULTI_INST_INTR
INTERRUPT_REMAIN_IN_QUEUE:
            info.intr_reason = dev->interrupt_reason[intr_inst_index];
            s_interrupt_flag[intr_inst_index] = 0;
            dev->interrupt_reason[intr_inst_index] = 0;
#else
            info.intr_reason = dev->interrupt_reason;
            s_interrupt_flag = 0;
            dev->interrupt_reason = 0;
#endif

#ifdef VPU_IRQ_CONTROL
            enable_irq(s_vpu_irq);
#endif
            ret = copy_to_user((void __user *)arg, &info, sizeof(vpudrv_intr_info_t));
            DPRINTK("[VPUDRV][-]VDI_IOCTL_WAIT_INTERRUPT\n");
            if (ret != 0)
            {
                return -EFAULT;
            }
        }
        break;

    case VDI_IOCTL_SET_CLOCK_GATE:
        {
            u32 clkgate;

            DPRINTK("[VPUDRV][+]VDI_IOCTL_SET_CLOCK_GATE\n");
            if (get_user(clkgate, (u32 __user *) arg))
                return -EFAULT;
#ifdef VPU_SUPPORT_CLOCK_CONTROL
            if (clkgate)
                vpu_clk_enable(s_vpu_clk);
            else
                vpu_clk_disable(s_vpu_clk);
#endif
            DPRINTK("[VPUDRV][-]VDI_IOCTL_SET_CLOCK_GATE\n");

        }
        break;
    case VDI_IOCTL_GET_INSTANCE_POOL:
        {
            DPRINTK("[VPUDRV][+]VDI_IOCTL_GET_INSTANCE_POOL\n");
            if ((ret = down_interruptible(&s_vpu_sem)) == 0) {
                if (s_instance_pool.base != 0) {
                    ret = copy_to_user((void __user *)arg, &s_instance_pool, sizeof(vpudrv_buffer_t));
                    if (ret != 0)
                        ret = -EFAULT;
                } else {
                    ret = copy_from_user(&s_instance_pool, (vpudrv_buffer_t *)arg, sizeof(vpudrv_buffer_t));
                    if (ret == 0) {
    #ifdef USE_VMALLOC_FOR_INSTANCE_POOL_MEMORY
                    s_instance_pool.size = PAGE_ALIGN(s_instance_pool.size);
                    s_instance_pool.base = (unsigned long)vmalloc(s_instance_pool.size);
                    s_instance_pool.phys_addr = s_instance_pool.base;

                    if (s_instance_pool.base != 0)
    #else

                        if (vpu_alloc_dma_buffer(&s_instance_pool) != -1)
    #endif

                        {
                            memset((void *)s_instance_pool.base, 0x0, s_instance_pool.size); /*clearing memory*/
                            ret = copy_to_user((void __user *)arg, &s_instance_pool, sizeof(vpudrv_buffer_t));
                            if (ret == 0) {
                                /* success to get memory for instance pool */
                                up(&s_vpu_sem);
                                break;
                            }
                        }

                    }
                    ret = -EFAULT;
                }

                up(&s_vpu_sem);
            }

            DPRINTK("[VPUDRV][-]VDI_IOCTL_GET_INSTANCE_POOL\n");
        }
        break;
    case VDI_IOCTL_GET_COMMON_MEMORY:
        {
            DPRINTK("[VPUDRV][+]VDI_IOCTL_GET_COMMON_MEMORY\n");
            if (s_common_memory.base != 0) {
                ret = copy_to_user((void __user *)arg, &s_common_memory, sizeof(vpudrv_buffer_t));
                if (ret != 0)
                    ret = -EFAULT;
            } else {
                ret = copy_from_user(&s_common_memory, (vpudrv_buffer_t *)arg, sizeof(vpudrv_buffer_t));
                if (ret == 0) {
                    if (vpu_alloc_dma_buffer(&s_common_memory) != -1) {
                        ret = copy_to_user((void __user *)arg, &s_common_memory, sizeof(vpudrv_buffer_t));
                        if (ret == 0) {
                            /* success to get memory for common memory */
                            break;
                        }
                    }
                }

                ret = -EFAULT;
            }
            DPRINTK("[VPUDRV][-]VDI_IOCTL_GET_COMMON_MEMORY\n");
        }
        break;
    case VDI_IOCTL_OPEN_INSTANCE:
        {
            vpudrv_inst_info_t inst_info;
            vpudrv_instanace_list_t *vil, *n;

            vil = kzalloc(sizeof(*vil), GFP_KERNEL);
            if (!vil)
                return -ENOMEM;

            if (copy_from_user(&inst_info, (vpudrv_inst_info_t *)arg, sizeof(vpudrv_inst_info_t)))
                return -EFAULT;

            vil->inst_idx = inst_info.inst_idx;
            vil->core_idx = inst_info.core_idx;
            vil->filp = filp;

            spin_lock(&s_vpu_lock);
            list_add(&vil->list, &s_inst_list_head);

             inst_info.inst_open_count = 0; /* counting the current open instance number */
            list_for_each_entry_safe(vil, n, &s_inst_list_head, list)
            {
                if (vil->core_idx == inst_info.core_idx)
                    inst_info.inst_open_count++;
            }
#ifdef SUPPORT_MULTI_INST_INTR
            kfifo_reset(&s_interrupt_pending_q[inst_info.inst_idx]);
#endif
            spin_unlock(&s_vpu_lock);

            s_vpu_open_ref_count++; /* flag just for that vpu is in opened or closed */

            if (copy_to_user((void __user *)arg, &inst_info, sizeof(vpudrv_inst_info_t))) {
                                kfree(vil);
                return -EFAULT;
                        }

            DPRINTK("[VPUDRV] VDI_IOCTL_OPEN_INSTANCE core_idx=%d, inst_idx=%d, s_vpu_open_ref_count=%d, inst_open_count=%d\n", (int)inst_info.core_idx, (int)inst_info.inst_idx, s_vpu_open_ref_count, inst_info.inst_open_count);
        }
        break;
    case VDI_IOCTL_CLOSE_INSTANCE:
        {
            vpudrv_inst_info_t inst_info;
            vpudrv_instanace_list_t *vil, *n;
            u32 found = 0;

            DPRINTK("[VPUDRV][+]VDI_IOCTL_CLOSE_INSTANCE\n");
            if (copy_from_user(&inst_info, (vpudrv_inst_info_t *)arg, sizeof(vpudrv_inst_info_t)))
                return -EFAULT;

            spin_lock(&s_vpu_lock);
            list_for_each_entry_safe(vil, n, &s_inst_list_head, list)
            {
                if (vil->inst_idx == inst_info.inst_idx && vil->core_idx == inst_info.core_idx) {
                    list_del(&vil->list);
                    kfree(vil);
                    found = 1;
                    break;
                }
            }

            if (0 == found) {
                spin_unlock(&s_vpu_lock);
                return -EINVAL;
            }

            inst_info.inst_open_count = 0; /* counting the current open instance number */
            list_for_each_entry_safe(vil, n, &s_inst_list_head, list)
            {
                if (vil->core_idx == inst_info.core_idx)
                    inst_info.inst_open_count++;
            }
#ifdef SUPPORT_MULTI_INST_INTR
            kfifo_reset(&s_interrupt_pending_q[inst_info.inst_idx]);
#endif
            spin_unlock(&s_vpu_lock);

            s_vpu_open_ref_count--; /* flag just for that vpu is in opened or closed */

            if (copy_to_user((void __user *)arg, &inst_info, sizeof(vpudrv_inst_info_t)))
                return -EFAULT;

            DPRINTK("[VPUDRV] VDI_IOCTL_CLOSE_INSTANCE core_idx=%d, inst_idx=%d, s_vpu_open_ref_count=%d, inst_open_count=%d\n", (int)inst_info.core_idx, (int)inst_info.inst_idx, s_vpu_open_ref_count, inst_info.inst_open_count);
        }
        break;
    case VDI_IOCTL_GET_INSTANCE_NUM:
        {
            vpudrv_inst_info_t inst_info;
            vpudrv_instanace_list_t *vil, *n;
            DPRINTK("[VPUDRV][+]VDI_IOCTL_GET_INSTANCE_NUM\n");

            ret = copy_from_user(&inst_info, (vpudrv_inst_info_t *)arg, sizeof(vpudrv_inst_info_t));
            if (ret != 0)
                break;

            spin_lock(&s_vpu_lock);
            inst_info.inst_open_count = 0;
            list_for_each_entry_safe(vil, n, &s_inst_list_head, list)
            {
                if (vil->core_idx == inst_info.core_idx)
                    inst_info.inst_open_count++;
            }
            spin_unlock(&s_vpu_lock);

            ret = copy_to_user((void __user *)arg, &inst_info, sizeof(vpudrv_inst_info_t));

            DPRINTK("[VPUDRV] VDI_IOCTL_GET_INSTANCE_NUM core_idx=%d, inst_idx=%d, open_count=%d\n", (int)inst_info.core_idx, (int)inst_info.inst_idx, inst_info.inst_open_count);

        }
        break;
    case VDI_IOCTL_RESET:
        {
            vpu_hw_reset();
        }
        break;
    case VDI_IOCTL_GET_REGISTER_INFO:
        {
            DPRINTK("[VPUDRV][+]VDI_IOCTL_GET_REGISTER_INFO\n");
            ret = copy_to_user((void __user *)arg, &s_vpu_register, sizeof(vpudrv_buffer_t));
            if (ret != 0)
                ret = -EFAULT;
            DPRINTK("[VPUDRV][-]VDI_IOCTL_GET_REGISTER_INFO s_vpu_register.phys_addr==0x%lx, s_vpu_register.virt_addr=0x%lx, s_vpu_register.size=%d\n", s_vpu_register.phys_addr , s_vpu_register.virt_addr, s_vpu_register.size);
        }
        break;
    case VDI_IOCTL_FLUSH_DCACHE:
        {
            vpudrv_flush_cache_t cache_info;


            ret = copy_from_user(&cache_info, (vpudrv_flush_cache_t *)arg, sizeof(vpudrv_flush_cache_t));
            if (ret != 0)
                ret = -EFAULT;

            if(cache_info.flag)
                starfive_flush_dcache(cache_info.start,cache_info.size);
        }
	break;

    case VDI_IOCTL_CPUFREQ_SAVEENV:
        {
#if defined(CONFIG_CPU_FREQ) && defined(CONFIG_USE_PLL_DYNAMIC_FREQ)
	    vpu_freq_save_env();
#endif
        }
	break;
    case VDI_IOCTL_CPUFREQ_PUTENV:
        {
#if defined(CONFIG_CPU_FREQ) && defined(CONFIG_USE_PLL_DYNAMIC_FREQ)
	    vpu_freq_put_env();
#endif
        }
	break;

    default:
        {
            printk(KERN_ERR "[VPUDRV] No such IOCTL, cmd is %d\n", cmd);
        }
        break;
    }
    return ret;
}

static ssize_t vpu_read(struct file *filp, char __user *buf, size_t len, loff_t *ppos)
{

    return -1;
}

static ssize_t vpu_write(struct file *filp, const char __user *buf, size_t len, loff_t *ppos)
{

    /* DPRINTK("[VPUDRV] vpu_write len=%d\n", (int)len); */
    if (!buf) {
        printk(KERN_ERR "[VPUDRV] vpu_write buf = NULL error \n");
        return -EFAULT;
    }

    if (len == sizeof(vpu_bit_firmware_info_t)) {
        vpu_bit_firmware_info_t *bit_firmware_info;

        bit_firmware_info = kmalloc(sizeof(vpu_bit_firmware_info_t), GFP_KERNEL);
        if (!bit_firmware_info) {
            printk(KERN_ERR "[VPUDRV] vpu_write  bit_firmware_info allocation error \n");
            return -EFAULT;
        }

        if (copy_from_user(bit_firmware_info, buf, len)) {
            printk(KERN_ERR "[VPUDRV] vpu_write copy_from_user error for bit_firmware_info\n");
            return -EFAULT;
        }

        if (bit_firmware_info->size == sizeof(vpu_bit_firmware_info_t)) {
            DPRINTK("[VPUDRV] vpu_write set bit_firmware_info coreIdx=0x%x, reg_base_offset=0x%x size=0x%x, bit_code[0]=0x%x\n",
            bit_firmware_info->core_idx, (int)bit_firmware_info->reg_base_offset, bit_firmware_info->size, bit_firmware_info->bit_code[0]);

            if (bit_firmware_info->core_idx > MAX_NUM_VPU_CORE) {
                printk(KERN_ERR "[VPUDRV] vpu_write coreIdx[%d] is exceeded than MAX_NUM_VPU_CORE[%d]\n", bit_firmware_info->core_idx, MAX_NUM_VPU_CORE);
                return -ENODEV;
            }

            memcpy((void *)&s_bit_firmware_info[bit_firmware_info->core_idx], bit_firmware_info, sizeof(vpu_bit_firmware_info_t));
            kfree(bit_firmware_info);

            return len;
        }

        kfree(bit_firmware_info);
    }

    return -1;
}

static int vpu_release(struct inode *inode, struct file *filp)
{
    int ret = 0;
    u32 open_count;
#ifdef SUPPORT_MULTI_INST_INTR
    int i;
#endif
    DPRINTK("[VPUDRV] vpu_release\n");

    if ((ret = down_interruptible(&s_vpu_sem)) == 0) {

        /* found and free the not handled buffer by user applications */
        vpu_free_buffers(filp);

        /* found and free the not closed instance by user applications */
        vpu_free_instances(filp);
        spin_lock(&s_vpu_lock);
        s_vpu_drv_context.open_count--;
        open_count = s_vpu_drv_context.open_count;
        spin_unlock(&s_vpu_lock);
        if (open_count == 0) {
#ifdef SUPPORT_MULTI_INST_INTR
            for (i=0; i<MAX_NUM_INSTANCE; i++) {
                kfifo_reset(&s_interrupt_pending_q[i]);
            }
#endif
            if (s_instance_pool.base) {
                DPRINTK("[VPUDRV] free instance pool\n");
#ifdef USE_VMALLOC_FOR_INSTANCE_POOL_MEMORY
                vfree((const void *)s_instance_pool.base);
#else
                vpu_free_dma_buffer(&s_instance_pool);
#endif
                s_instance_pool.base = 0;
            }
        }
    }
    up(&s_vpu_sem);

    pm_runtime_put_sync(s_vpu_clk->dev);
    return 0;
}

static int vpu_fasync(int fd, struct file *filp, int mode)
{
    struct vpu_drv_context_t *dev = (struct vpu_drv_context_t *)filp->private_data;
    return fasync_helper(fd, filp, mode, &dev->async_queue);
}


static int vpu_map_to_register(struct file *fp, struct vm_area_struct *vm)
{
    unsigned long pfn;

    vm->vm_flags |= VM_IO | VM_RESERVED;
    vm->vm_page_prot = pgprot_noncached(vm->vm_page_prot);
    pfn = s_vpu_register.phys_addr >> PAGE_SHIFT;

    return remap_pfn_range(vm, vm->vm_start, pfn, vm->vm_end-vm->vm_start, vm->vm_page_prot) ? -EAGAIN : 0;
}

static int vpu_map_to_physical_memory(struct file *fp, struct vm_area_struct *vm)
{
    vm->vm_flags |= VM_IO | VM_RESERVED;
    vm->vm_page_prot = pgprot_noncached(vm->vm_page_prot);

    return remap_pfn_range(vm, vm->vm_start, vm->vm_pgoff, vm->vm_end-vm->vm_start, vm->vm_page_prot) ? -EAGAIN : 0;
}

static int vpu_map_to_instance_pool_memory(struct file *fp, struct vm_area_struct *vm)
{
#ifdef USE_VMALLOC_FOR_INSTANCE_POOL_MEMORY
    int ret;
    long length = vm->vm_end - vm->vm_start;
    unsigned long start = vm->vm_start;
    char *vmalloc_area_ptr = (char *)s_instance_pool.base;
    unsigned long pfn;

    vm->vm_flags |= VM_RESERVED;

    /* loop over all pages, map it page individually */
    while (length > 0)
    {
        pfn = vmalloc_to_pfn(vmalloc_area_ptr);
        if ((ret = remap_pfn_range(vm, start, pfn, PAGE_SIZE, PAGE_SHARED)) < 0) {
                return ret;
        }
        start += PAGE_SIZE;
        vmalloc_area_ptr += PAGE_SIZE;
        length -= PAGE_SIZE;
    }

    return 0;
#else
    vm->vm_flags |= VM_RESERVED;
    return remap_pfn_range(vm, vm->vm_start, vm->vm_pgoff, vm->vm_end-vm->vm_start, vm->vm_page_prot) ? -EAGAIN : 0;
#endif
}

/*!
 * @brief memory map interface for vpu file operation
 * @return  0 on success or negative error code on error
 */
static int vpu_mmap(struct file *fp, struct vm_area_struct *vm)
{
#ifdef USE_VMALLOC_FOR_INSTANCE_POOL_MEMORY
    if (vm->vm_pgoff == 0)
        return vpu_map_to_instance_pool_memory(fp, vm);

    if (vm->vm_pgoff == (s_vpu_register.phys_addr>>PAGE_SHIFT))
        return vpu_map_to_register(fp, vm);

    return vpu_map_to_physical_memory(fp, vm);
#else
    if (vm->vm_pgoff) {
        if (vm->vm_pgoff == (s_instance_pool.phys_addr>>PAGE_SHIFT))
            return vpu_map_to_instance_pool_memory(fp, vm);

        return vpu_map_to_physical_memory(fp, vm);
    } else {
        return vpu_map_to_register(fp, vm);
    }
#endif
}

struct file_operations vpu_fops = {
    .owner = THIS_MODULE,
    .open = vpu_open,
    .read = vpu_read,
    .write = vpu_write,
    /*.ioctl = vpu_ioctl, // for kernel 2.6.9 of C&M*/
    .unlocked_ioctl = vpu_ioctl,
    .release = vpu_release,
    .fasync = vpu_fasync,
    .mmap = vpu_mmap,
};

static int vpu_probe(struct platform_device *pdev)
{
    int err = 0;
    struct resource *res = NULL;
    struct device *devices;
#ifdef VPU_SUPPORT_RESERVED_VIDEO_MEMORY
	struct resource res_cma;
	struct device_node *node;
#endif
	int irq = -1;
    DPRINTK("[VPUDRV] vpu_probe\n");
	if(pdev){
		vpu_dev = &pdev->dev;
		vpu_dev->coherent_dma_mask = 0xffffffff;;
		dev_info(vpu_dev,"device init.\n");
	}
    if (pdev)
        res = platform_get_resource(pdev, IORESOURCE_MEM, 0);
    if (res) {/* if platform driver is implemented */
        s_vpu_register.phys_addr = res->start;
        s_vpu_register.virt_addr = (unsigned long)ioremap_nocache(res->start, res->end - res->start);
        s_vpu_register.size = res->end - res->start;
        DPRINTK("[VPUDRV] : vpu base address get from platform driver physical base addr==0x%lx, virtual base=0x%lx\n", s_vpu_register.phys_addr , s_vpu_register.virt_addr);
    } else {
        s_vpu_register.phys_addr = VPU_REG_BASE_ADDR;
        s_vpu_register.virt_addr = (unsigned long)ioremap_nocache(s_vpu_register.phys_addr, VPU_REG_SIZE);
        s_vpu_register.size = VPU_REG_SIZE;
        DPRINTK("[VPUDRV] : vpu base address get from defined value physical base addr==0x%lx, virtual base=0x%lx\n", s_vpu_register.phys_addr, s_vpu_register.virt_addr);

    }

    /* get the major number of the character device */
    if ((alloc_chrdev_region(&s_vpu_devt, 0, 1, VPU_DEV_NAME)) < 0) {
        err = -EBUSY;
        printk(KERN_ERR "could not allocate major number\n");
        goto ERROR_PROVE_DEVICE;
    }
    printk(KERN_INFO "SUCCESS alloc_chrdev_region\n");

    s_vpu_major = MAJOR(s_vpu_devt);
    /* initialize the device structure and register the device with the kernel */
    cdev_init(&s_vpu_cdev, &vpu_fops);
    if ((cdev_add(&s_vpu_cdev, s_vpu_devt, 1)) < 0) {
        err = -EBUSY;
        printk(KERN_ERR "could not allocate chrdev\n");

        goto ERROR_PROVE_DEVICE;
    }

    s_vpu_class = class_create(THIS_MODULE, VPU_DEV_NAME);
    if (IS_ERR(s_vpu_class)) {
	dev_err(vpu_dev, "class creat error.\n");
	goto ERROR_CRART_CLASS;
    }

    devices = device_create(s_vpu_class, 0, MKDEV(s_vpu_major, 0),
				NULL, VPU_DEV_NAME);
    if (IS_ERR(devices)) {
	dev_err(vpu_dev, "device creat error.\n");
	goto ERROR_CREAT_DEVICE;
    }

    if (pdev)
        s_vpu_clk = vpu_clk_get(pdev);
    else
        s_vpu_clk = vpu_clk_get(NULL);

    if (!s_vpu_clk)
        printk(KERN_ERR "[VPUDRV] : not support clock controller.\n");
    else
        DPRINTK("[VPUDRV] : get clock controller s_vpu_clk=%p\n", s_vpu_clk);

#if defined(CONFIG_CPU_FREQ) && defined(CONFIG_USE_PLL_DYNAMIC_FREQ)
    vpu_freq_init(&pdev->dev);
#endif
    vpu_pmu_enable(s_vpu_clk->dev);
    vpu_clk_enable(s_vpu_clk);
    reset_control_deassert(s_vpu_clk->resets);

#ifdef VPU_SUPPORT_ISR
#ifdef VPU_SUPPORT_PLATFORM_DRIVER_REGISTER
    if (pdev)
        irq = platform_get_irq(pdev, 0);
    if (irq >= 0) {/* if platform driver is implemented */
        s_vpu_irq = irq;
        DPRINTK("[VPUDRV] : vpu irq number get from platform driver irq=0x%x\n", s_vpu_irq);
    } else {
        DPRINTK("[VPUDRV] : vpu irq number get from defined value irq=0x%x\n", s_vpu_irq);
    }
#else
    DPRINTK("[VPUDRV] : vpu irq number get from defined value irq=0x%x\n", s_vpu_irq);
#endif

    err = request_irq(s_vpu_irq, vpu_irq_handler, 0, pdev->name, (void *)(&s_vpu_drv_context));
    if (err) {
        printk(KERN_ERR "[VPUDRV] :  fail to register interrupt handler\n");
        goto ERROR_PROVE_DEVICE;
    }
#endif


#ifdef VPU_SUPPORT_RESERVED_VIDEO_MEMORY
	node = of_parse_phandle(vpu_dev->of_node, "memory-region", 0);
	if(node){
		dev_info(vpu_dev, "Get mem form memory-region\n");
		of_address_to_resource(node, 0, &res_cma);
		s_video_memory.size = resource_size(&res_cma);
    	s_video_memory.phys_addr = res_cma.start;
	}else{
        dev_info(vpu_dev, "Get mem form memory-region fiiled.please check the dts file.\n");
		return 0;
	}
    s_video_memory.base = (unsigned long)ioremap_nocache(DRAM_MEM2SYS(s_video_memory.phys_addr), PAGE_ALIGN(s_video_memory.size));
    if (!s_video_memory.base) {
        printk(KERN_ERR "[VPUDRV] :  fail to remap video memory physical phys_addr=0x%lx, base=0x%lx, size=%d\n", s_video_memory.phys_addr, s_video_memory.base, (int)s_video_memory.size);
        goto ERROR_PROVE_DEVICE;
    }

    if (vmem_init(&s_vmem, s_video_memory.phys_addr, s_video_memory.size) < 0) {
        printk(KERN_ERR "[VPUDRV] :  fail to init vmem system\n");
        goto ERROR_PROVE_DEVICE;
    }
    DPRINTK("[VPUDRV] success to probe vpu device with reserved video memory phys_addr=0x%lx, base=0x%lx, size=%d\n", s_video_memory.phys_addr, s_video_memory.base,s_video_memory.size);
#else
    DPRINTK("[VPUDRV] success to probe vpu device with non reserved video memory\n");
#endif

    return 0;

ERROR_CREAT_DEVICE:
	class_destroy(s_vpu_class);
ERROR_CRART_CLASS:
	cdev_del(&s_vpu_cdev);
ERROR_PROVE_DEVICE:

    if (s_vpu_major)
        unregister_chrdev_region(s_vpu_major, 1);

    if (s_vpu_register.virt_addr)
        iounmap((void *)s_vpu_register.virt_addr);

    return err;
}
#ifdef VPU_SUPPORT_PLATFORM_DRIVER_REGISTER
static int vpu_remove(struct platform_device *pdev)
{
    DPRINTK("[VPUDRV] vpu_remove\n");

    if (s_instance_pool.base) {
#ifdef USE_VMALLOC_FOR_INSTANCE_POOL_MEMORY
        vfree((const void *)s_instance_pool.base);
#else
        vpu_free_dma_buffer(&s_instance_pool);
#endif
        s_instance_pool.base = 0;
    }

    if (s_common_memory.base) {
        vpu_free_dma_buffer(&s_common_memory);
        s_common_memory.base = 0;
    }

#ifdef VPU_SUPPORT_RESERVED_VIDEO_MEMORY
    if (s_video_memory.base) {
        iounmap((void *)s_video_memory.base);
        s_video_memory.base = 0;
        vmem_exit(&s_vmem);
    }
#endif

    if (s_vpu_major > 0) {
        device_destroy(s_vpu_class, MKDEV(s_vpu_major, 0));
        class_destroy(s_vpu_class);
        cdev_del(&s_vpu_cdev);
        unregister_chrdev_region(s_vpu_devt, 1);
        s_vpu_major = 0;
    }

#ifdef VPU_SUPPORT_ISR
    if (s_vpu_irq)
        free_irq(s_vpu_irq, &s_vpu_drv_context);
#endif

    if (s_vpu_register.virt_addr)
        iounmap((void *)s_vpu_register.virt_addr);

    vpu_clk_put(s_vpu_clk);
    vpu_pmu_disable(s_vpu_clk->dev);

    return 0;
}
#endif /*VPU_SUPPORT_PLATFORM_DRIVER_REGISTER*/

#if defined(VPU_SUPPORT_PLATFORM_DRIVER_REGISTER) && defined(CONFIG_PM)
#define W5_MAX_CODE_BUF_SIZE    (512*1024)
#define W5_CMD_INIT_VPU         (0x0001)
#define W5_CMD_SLEEP_VPU        (0x0004)
#define W5_CMD_WAKEUP_VPU       (0x0002)

static void Wave5BitIssueCommand(int core, u32 cmd)
{
    WriteVpuRegister(W5_VPU_BUSY_STATUS, 1);
    WriteVpuRegister(W5_COMMAND, cmd);
    WriteVpuRegister(W5_VPU_HOST_INT_REQ, 1);

    return;
}

static int __maybe_unused  vpu_runtime_suspend(struct device *dev)
{
	reset_control_assert(s_vpu_clk->resets);
	vpu_clk_disable(s_vpu_clk);
	return 0;
}

static int __maybe_unused vpu_runtime_resume(struct device *dev)
{
	vpu_clk_enable(s_vpu_clk);
	return reset_control_deassert(s_vpu_clk->resets);
}

#ifdef CONFIG_PM_SLEEP
static int __maybe_unused vpu_suspend(struct device *dev)
{
    int i;
    int core;
    unsigned long timeout = jiffies + HZ;   /* vpu wait timeout to 1sec */
    int product_code;

    DPRINTK("[VPUDRV] vpu_suspend\n");
    pm_runtime_get_sync(dev);

    if (s_vpu_open_ref_count > 0) {
        for (core = 0; core < MAX_NUM_VPU_CORE; core++) {
            if (s_bit_firmware_info[core].size == 0)
                continue;
            product_code = ReadVpuRegister(VPU_PRODUCT_CODE_REGISTER);
            if (PRODUCT_CODE_W_SERIES(product_code)) {

                while (ReadVpuRegister(W5_VPU_BUSY_STATUS)) {
                    if (time_after(jiffies, timeout)) {
                        DPRINTK("SLEEP_VPU BUSY timeout");
                        goto DONE_SUSPEND;
                    }
                }

                Wave5BitIssueCommand(core, W5_CMD_SLEEP_VPU);

                while (ReadVpuRegister(W5_VPU_BUSY_STATUS)) {
                    if (time_after(jiffies, timeout)) {
                        DPRINTK("SLEEP_VPU BUSY timeout");
                        goto DONE_SUSPEND;
                    }
                }
                if (ReadVpuRegister(W5_RET_SUCCESS) == 0) {
                    DPRINTK("SLEEP_VPU failed [0x%x]", ReadVpuRegister(W5_RET_FAIL_REASON));
                    goto DONE_SUSPEND;
                }
            }
            else if (PRODUCT_CODE_NOT_W_SERIES(product_code)) {
                while (ReadVpuRegister(BIT_BUSY_FLAG)) {
                    if (time_after(jiffies, timeout))
                        goto DONE_SUSPEND;
                }

                for (i = 0; i < 64; i++)
                    s_vpu_reg_store[core][i] = ReadVpuRegister(BIT_BASE+(0x100+(i * 4)));
            }
            else {
                DPRINTK("[VPUDRV] Unknown product id : %08x\n", product_code);
                goto DONE_SUSPEND;
            }
        }
    }

DONE_SUSPEND:
    pm_runtime_put_sync(dev);
    pm_runtime_force_suspend(dev);

    return 0;
}

static int __maybe_unused vpu_resume(struct device *dev)
{
    int i;
    int core;
    u32 val;
    unsigned long timeout = jiffies + HZ;   /* vpu wait timeout to 1sec */
    int product_code;

    unsigned long   code_base;
    u32         code_size;
    u32         remap_size;
    int          regVal;
    u32         hwOption  = 0;


    DPRINTK("[VPUDRV] vpu_resume\n");

    pm_runtime_force_resume(dev);
    pm_runtime_get_sync(dev);

    for (core = 0; core < MAX_NUM_VPU_CORE; core++) {

        if (s_bit_firmware_info[core].size == 0) {
            continue;
        }
        product_code = ReadVpuRegister(VPU_PRODUCT_CODE_REGISTER);
        if (PRODUCT_CODE_W_SERIES(product_code)) {
            code_base = s_common_memory.phys_addr;
            /* ALIGN TO 4KB */
            code_size = (W5_MAX_CODE_BUF_SIZE&~0xfff);
            if (code_size < s_bit_firmware_info[core].size*2) {
                goto DONE_WAKEUP;
            }

            regVal = 0;
            WriteVpuRegister(W5_PO_CONF, regVal);

            /* Reset All blocks */
            regVal = 0x7ffffff;
            WriteVpuRegister(W5_VPU_RESET_REQ, regVal); /*Reset All blocks*/

            /* Waiting reset done */
            while (ReadVpuRegister(W5_VPU_RESET_STATUS)) {
                if (time_after(jiffies, timeout))
                    goto DONE_WAKEUP;
            }
            WriteVpuRegister(W5_VPU_RESET_REQ, 0);

            /* remap page size */
            remap_size = (code_size >> 12) & 0x1ff;
            regVal = 0x80000000 | (W5_REMAP_CODE_INDEX<<12) | (0 << 16) | (1<<11) | remap_size;
            WriteVpuRegister(W5_VPU_REMAP_CTRL, regVal);
            WriteVpuRegister(W5_VPU_REMAP_VADDR,0x00000000);    /* DO NOT CHANGE! */
            WriteVpuRegister(W5_VPU_REMAP_PADDR,code_base);
            WriteVpuRegister(W5_ADDR_CODE_BASE, code_base);
            WriteVpuRegister(W5_CODE_SIZE,      code_size);
            WriteVpuRegister(W5_CODE_PARAM,     0);
            WriteVpuRegister(W5_INIT_VPU_TIME_OUT_CNT,   timeout);

            WriteVpuRegister(W5_HW_OPTION, hwOption);

            /* Interrupt */
            if (product_code == WAVE521_CODE || product_code == WAVE521C_CODE ) {
                regVal  = (1<<INT_WAVE5_ENC_SET_PARAM);
                regVal |= (1<<INT_WAVE5_ENC_PIC);
                regVal |= (1<<INT_WAVE5_INIT_SEQ);
                regVal |= (1<<INT_WAVE5_DEC_PIC);
                regVal |= (1<<INT_WAVE5_BSBUF_EMPTY);
            }
            else {
                // decoder
                regVal  = (1<<INT_WAVE5_INIT_SEQ);
                regVal |= (1<<INT_WAVE5_DEC_PIC);
                regVal |= (1<<INT_WAVE5_BSBUF_EMPTY);
            }

            WriteVpuRegister(W5_VPU_VINT_ENABLE,  regVal);

            Wave5BitIssueCommand(core, W5_CMD_WAKEUP_VPU);
            WriteVpuRegister(W5_VPU_REMAP_CORE_START, 1);

            while (ReadVpuRegister(W5_VPU_BUSY_STATUS)) {
                if (time_after(jiffies, timeout))
                    goto DONE_WAKEUP;
            }

            if (ReadVpuRegister(W5_RET_SUCCESS) == 0) {
                DPRINTK("WAKEUP_VPU failed [0x%x]", ReadVpuRegister(W5_RET_FAIL_REASON));
                goto DONE_WAKEUP;
            }
        }
        else if (PRODUCT_CODE_NOT_W_SERIES(product_code)) {
            WriteVpuRegister(BIT_CODE_RUN, 0);

            /*---- LOAD BOOT CODE*/
            for (i = 0; i < 512; i++) {
                val = s_bit_firmware_info[core].bit_code[i];
                WriteVpuRegister(BIT_CODE_DOWN, ((i << 16) | val));
            }

            for (i = 0 ; i < 64 ; i++)
                WriteVpuRegister(BIT_BASE+(0x100+(i * 4)), s_vpu_reg_store[core][i]);

            WriteVpuRegister(BIT_BUSY_FLAG, 1);
            WriteVpuRegister(BIT_CODE_RESET, 1);
            WriteVpuRegister(BIT_CODE_RUN, 1);

            while (ReadVpuRegister(BIT_BUSY_FLAG)) {
                if (time_after(jiffies, timeout))
                    goto DONE_WAKEUP;
            }
        }
        else {
            DPRINTK("[VPUDRV] Unknown product id : %08x\n", product_code);
            goto DONE_WAKEUP;
        }
    }

DONE_WAKEUP:
    pm_runtime_put_sync(dev);

    return 0;
}
#endif	/* CONFIG_PM_SLEEP */
#endif	/* !CONFIG_PM */

#ifdef VPU_SUPPORT_PLATFORM_DRIVER_REGISTER

static const struct of_device_id cm_vpu_match[] = {
    {
        .compatible = "c&m,cm511-vpu",
    },
    {
        .compatible = "starfive,vdec",
    },
    {
        /* end of table */
    },
};
MODULE_DEVICE_TABLE(of, cm_vpu_match);

static const struct dev_pm_ops cm_vpu_pm_ops = {
	SET_RUNTIME_PM_OPS(vpu_runtime_suspend,
			   vpu_runtime_resume, NULL)
	SET_SYSTEM_SLEEP_PM_OPS(vpu_suspend, vpu_resume)
};

static struct platform_driver vpu_driver = {
    .driver = {
           .name = VPU_PLATFORM_DEVICE_NAME,
           .of_match_table = cm_vpu_match,
           .pm = &cm_vpu_pm_ops,
    },
    .probe = vpu_probe,
    .remove = vpu_remove,
};
#endif /* VPU_SUPPORT_PLATFORM_DRIVER_REGISTER */

static int __init vpu_init(void)
{
    int res;
#ifdef SUPPORT_MULTI_INST_INTR
    int i;
#endif
    DPRINTK("[VPUDRV] begin vpu_init\n");
#ifdef SUPPORT_MULTI_INST_INTR
    for (i=0; i<MAX_NUM_INSTANCE; i++) {
        init_waitqueue_head(&s_interrupt_wait_q[i]);
    }

    for (i=0; i<MAX_NUM_INSTANCE; i++) {
#define MAX_INTERRUPT_QUEUE (16*MAX_NUM_INSTANCE)
        res = kfifo_alloc(&s_interrupt_pending_q[i], MAX_INTERRUPT_QUEUE*sizeof(u32), GFP_KERNEL);
        if (res) {
            DPRINTK("[VPUDRV] kfifo_alloc failed 0x%x\n", res);
        }
    }
#else
    init_waitqueue_head(&s_interrupt_wait_q);
#endif
    s_common_memory.base = 0;
    s_instance_pool.base = 0;
#ifdef VPU_SUPPORT_PLATFORM_DRIVER_REGISTER
    res = platform_driver_register(&vpu_driver);
#else
    res = vpu_probe(NULL);
#endif /* VPU_SUPPORT_PLATFORM_DRIVER_REGISTER */

    DPRINTK("[VPUDRV] end vpu_init result=0x%x\n", res);
    return res;
}

static void __exit vpu_exit(void)
{
#ifdef VPU_SUPPORT_PLATFORM_DRIVER_REGISTER
    DPRINTK("[VPUDRV] vpu_exit\n");

    platform_driver_unregister(&vpu_driver);

#else /* VPU_SUPPORT_PLATFORM_DRIVER_REGISTER */

#ifdef VPU_SUPPORT_CLOCK_CONTROL
#else
    vpu_clk_disable(s_vpu_clk);
#endif
    vpu_clk_put(s_vpu_clk);

    if (s_instance_pool.base) {
#ifdef USE_VMALLOC_FOR_INSTANCE_POOL_MEMORY
        vfree((const void *)s_instance_pool.base);
#else
        vpu_free_dma_buffer(&s_instance_pool);
#endif
        s_instance_pool.base = 0;
    }

    if (s_common_memory.base) {
        vpu_free_dma_buffer(&s_common_memory);
        s_common_memory.base = 0;
    }

#if defined(CONFIG_CPU_FREQ) && defined(CONFIG_USE_PLL_DYNAMIC_FREQ)
	vpu_freq_close();
#endif

#ifdef VPU_SUPPORT_RESERVED_VIDEO_MEMORY
    if (s_video_memory.base) {
        iounmap((void *)s_video_memory.base);
        s_video_memory.base = 0;

        vmem_exit(&s_vmem);
    }
#endif

    if (s_vpu_major > 0) {
	device_destroy(s_vpu_class, MKDEV(s_vpu_major, 0));
	class_destroy(s_vpu_class);
	cdev_del(&s_vpu_cdev);
	unregister_chrdev_region(s_vpu_devt, 1);
	s_vpu_major = 0;
    }

#ifdef VPU_SUPPORT_ISR
    if (s_vpu_irq)
        free_irq(s_vpu_irq, &s_vpu_drv_context);
#endif

#ifdef SUPPORT_MULTI_INST_INTR
    {
        int i;
        for (i=0; i<MAX_NUM_INSTANCE; i++) {
            kfifo_free(&s_interrupt_pending_q[i]);
        }
    }
#endif

    if (s_vpu_register.virt_addr) {
        iounmap((void *)s_vpu_register.virt_addr);
        s_vpu_register.virt_addr = 0x00;
    }

#endif /* VPU_SUPPORT_PLATFORM_DRIVER_REGISTER */

    return;
}

MODULE_AUTHOR("A customer using C&M VPU, Inc.");
MODULE_DESCRIPTION("VPU linux driver");
MODULE_LICENSE("Dual BSD/GPL");

module_init(vpu_init);
module_exit(vpu_exit);

static int vpu_pmu_enable(struct device *dev)
{
	pm_runtime_set_active(dev);
	pm_runtime_enable(dev);
	return 0;
}

static void vpu_pmu_disable(struct device *dev)
{
	pm_runtime_disable(dev);
	pm_runtime_set_suspended(dev);
}

/* clk&reset for starfive jh7110*/
#ifndef STARFIVE_VPU_SUPPORT_CLOCK_CONTROL

#define CLK_ENABLE_DATA			1
#define CLK_DISABLE_DATA		0
#define CLK_EN_SHIFT			31
#define CLK_EN_MASK			0x80000000U

#define SAIF_BD_APBS_BASE		0x13020000
#define WAVE511_CLK_AXI_CTRL		0x118U
#define WAVE511_CLK_BPU_CTRL		0x11cU
#define WAVE511_CLK_VCE_CTRL		0x120U
#define WAVE511_CLK_APB_CTRL		0x124U
#define WAVE511_CLK_NOCBUS_CTRL 	0x130U

#define RSTGEN_SOFTWARE_RESET_ASSERT1	0x2FCU
#define RSTGEN_SOFTWARE_RESET_STATUS1	0x30CU

#define RSTN_AXI_MASK			(0x1 << 15)
#define RSTN_BPU_MASK			(0x1 << 16)
#define RSTN_VCE_MASK			(0x1 << 17)
#define RSTN_APB_MASK			(0x1 << 18)
#define RSTN_128B_AXIMEM_MASK		(0x1 << 21)

static uint32_t saif_get_reg(const volatile void __iomem *addr,
			uint32_t shift, uint32_t mask)
{
	u32 tmp;
	tmp = readl(addr);
	tmp = (tmp & mask) >> shift;
	return tmp;
}

static void saif_set_reg(volatile void __iomem *addr, uint32_t data,
			uint32_t shift, uint32_t mask)
{
	uint32_t tmp;

	tmp = readl(addr);
	tmp &= ~mask;
	tmp |= (data << shift) & mask;
	writel(tmp, addr);
}

static void saif_assert_rst(volatile void __iomem *addr,
			const volatile void __iomem *addr_status, uint32_t mask)
{
	uint32_t tmp;

	tmp = readl(addr);
	tmp |= mask;
	writel(tmp, addr);
	do {
		tmp = readl(addr_status);
	} while ((tmp & mask) != 0);
}

static void saif_clear_rst(volatile void __iomem *addr,
			const volatile void __iomem *addr_status, uint32_t mask)
{
	uint32_t tmp;

	tmp = readl(addr);
	tmp &= ~mask;
	writel(tmp, addr);
	do {
		tmp = readl(addr_status);
	} while ((tmp & mask) != mask);
}

static void vpu_noc_vdec_bus_control(vpu_clk_t *clk, bool enable)
{
	if (enable)
		saif_set_reg(clk->noc_bus, CLK_ENABLE_DATA, clk->en_shift, clk->en_mask);
	else
		saif_set_reg(clk->noc_bus, CLK_DISABLE_DATA, clk->en_shift, clk->en_mask);
}

static void vpu_clk_control(vpu_clk_t *clk, bool enable)
{
	if (enable) {
		/*enable*/
		saif_set_reg(clk->apb_clk.en_ctrl, CLK_ENABLE_DATA, clk->en_shift, clk->en_mask);
		saif_set_reg(clk->axi_clk.en_ctrl, CLK_ENABLE_DATA, clk->en_shift, clk->en_mask);
		saif_set_reg(clk->bpu_clk.en_ctrl, CLK_ENABLE_DATA, clk->en_shift, clk->en_mask);
		saif_set_reg(clk->vce_clk.en_ctrl, CLK_ENABLE_DATA, clk->en_shift, clk->en_mask);

		/*clr-reset*/
		saif_clear_rst(clk->rst_ctrl, clk->rst_status, clk->apb_clk.rst_mask);
		saif_clear_rst(clk->rst_ctrl, clk->rst_status, clk->axi_clk.rst_mask);
		saif_clear_rst(clk->rst_ctrl, clk->rst_status, clk->bpu_clk.rst_mask);
		saif_clear_rst(clk->rst_ctrl, clk->rst_status, clk->vce_clk.rst_mask);
		saif_clear_rst(clk->rst_ctrl, clk->rst_status, clk->aximem_128b.rst_mask);
	} else {
		/*assert-reset*/
		saif_assert_rst(clk->rst_ctrl, clk->rst_status, clk->apb_clk.rst_mask);
		saif_assert_rst(clk->rst_ctrl, clk->rst_status, clk->axi_clk.rst_mask);
		saif_assert_rst(clk->rst_ctrl, clk->rst_status, clk->bpu_clk.rst_mask);
		saif_assert_rst(clk->rst_ctrl, clk->rst_status, clk->vce_clk.rst_mask);
		saif_assert_rst(clk->rst_ctrl, clk->rst_status, clk->aximem_128b.rst_mask);

		/*disable*/
		saif_set_reg(clk->apb_clk.en_ctrl, CLK_DISABLE_DATA, clk->en_shift, clk->en_mask);
		saif_set_reg(clk->axi_clk.en_ctrl, CLK_DISABLE_DATA, clk->en_shift, clk->en_mask);
		saif_set_reg(clk->bpu_clk.en_ctrl, CLK_DISABLE_DATA, clk->en_shift, clk->en_mask);
		saif_set_reg(clk->vce_clk.en_ctrl, CLK_DISABLE_DATA, clk->en_shift, clk->en_mask);
	}
}

static void vpu_clk_reset(vpu_clk_t *clk)
{
	/*assert-reset*/
	saif_assert_rst(clk->rst_ctrl, clk->rst_status, clk->apb_clk.rst_mask);
	saif_assert_rst(clk->rst_ctrl, clk->rst_status, clk->axi_clk.rst_mask);
	saif_assert_rst(clk->rst_ctrl, clk->rst_status, clk->bpu_clk.rst_mask);
	saif_assert_rst(clk->rst_ctrl, clk->rst_status, clk->vce_clk.rst_mask);

	/*clr-reset*/
	saif_clear_rst(clk->rst_ctrl, clk->rst_status, clk->apb_clk.rst_mask);
	saif_clear_rst(clk->rst_ctrl, clk->rst_status, clk->axi_clk.rst_mask);
	saif_clear_rst(clk->rst_ctrl, clk->rst_status, clk->bpu_clk.rst_mask);
	saif_clear_rst(clk->rst_ctrl, clk->rst_status, clk->vce_clk.rst_mask);
}

int vpu_hw_reset(void)
{
	if (!s_vpu_clk)
		return -1;

	vpu_clk_reset(s_vpu_clk);

	DPRINTK("[VPUDRV] reset vpu hardware. \n");
	return 0;
}

static int vpu_of_clk_get(struct platform_device *pdev, vpu_clk_t *vpu_clk)
{
	if (!pdev)
		return -ENXIO;

	vpu_clk->clkgen = ioremap(SAIF_BD_APBS_BASE, 0x400);
	if (IS_ERR(vpu_clk->clkgen)) {
		dev_err(&pdev->dev, "ioremap clkgen failed.\n");
		return PTR_ERR(vpu_clk->clkgen);
	}

	/* clkgen define */
	vpu_clk->axi_clk.en_ctrl = vpu_clk->clkgen + WAVE511_CLK_AXI_CTRL;
	vpu_clk->bpu_clk.en_ctrl = vpu_clk->clkgen + WAVE511_CLK_BPU_CTRL;
	vpu_clk->vce_clk.en_ctrl = vpu_clk->clkgen + WAVE511_CLK_VCE_CTRL;
	vpu_clk->apb_clk.en_ctrl = vpu_clk->clkgen + WAVE511_CLK_APB_CTRL;
	vpu_clk->noc_bus = vpu_clk->clkgen + WAVE511_CLK_NOCBUS_CTRL;
	vpu_clk->en_mask = CLK_EN_MASK;
	vpu_clk->en_shift = CLK_EN_SHIFT;

	/* rstgen define */
	vpu_clk->rst_ctrl = vpu_clk->clkgen + RSTGEN_SOFTWARE_RESET_ASSERT1;
	vpu_clk->rst_status = vpu_clk->clkgen + RSTGEN_SOFTWARE_RESET_STATUS1;
	vpu_clk->axi_clk.rst_mask = RSTN_AXI_MASK;
	vpu_clk->bpu_clk.rst_mask = RSTN_BPU_MASK;
	vpu_clk->vce_clk.rst_mask = RSTN_VCE_MASK;
	vpu_clk->apb_clk.rst_mask = RSTN_APB_MASK;
	vpu_clk->aximem_128b.rst_mask = RSTN_128B_AXIMEM_MASK;

	if (device_property_read_bool(&pdev->dev, "starfive,vdec_noc_ctrl"))
		vpu_clk->noc_ctrl = true;

	return 0;
}

static vpu_clk_t *vpu_clk_get(struct platform_device *pdev)
{
	vpu_clk_t *vpu_clk;

	vpu_clk = devm_kzalloc(&pdev->dev, sizeof(*vpu_clk), GFP_KERNEL);
	if (!vpu_clk)
		return NULL;

	if (vpu_of_clk_get(pdev, vpu_clk))
		goto err_get_clk;

	return vpu_clk;
err_get_clk:
	devm_kfree(&pdev->dev, vpu_clk);
	return NULL;
}

static void vpu_clk_put(vpu_clk_t *clk)
{
	if (clk->clkgen) {
		iounmap(clk->clkgen);
		clk->clkgen = NULL;
	}
}

static int vpu_clk_enable(vpu_clk_t *clk)
{
	if (clk == NULL || IS_ERR(clk))
		return -1;

	vpu_pmu_enable(clk->dev);

	vpu_clk_control(clk, true);

	if (clk->noc_ctrl == true)
		vpu_noc_vdec_bus_control(clk, true);

	DPRINTK("[VPUDRV] vpu_clk_enable\n");
	return 0;
}

static void vpu_clk_disable(vpu_clk_t *clk)
{
	if (clk == NULL || IS_ERR(clk))
		return;

	vpu_clk_control(clk, false);
	vpu_pmu_disable(clk->dev);
	if (clk->noc_ctrl == true)
		vpu_noc_vdec_bus_control(clk, false);

	DPRINTK("[VPUDRV] vpu_clk_disable\n");
}

#else  /*STARFIVE_VPU_SUPPORT_CLOCK_CONTROL*/
int vpu_hw_reset(void)
{
	DPRINTK("[VPUDRV] reset vpu hardware. \n");
	/* sram do not need reset */
	return reset_control_reset(s_vpu_clk->resets);
}

static int vpu_of_clk_get(struct platform_device *pdev, vpu_clk_t *vpu_clk)
{
	struct device *dev = &pdev->dev;
	int ret;

	vpu_clk->dev = dev;
	vpu_clk->clks = vpu_clks;
	vpu_clk->nr_clks = ARRAY_SIZE(vpu_clks);

	vpu_clk->resets = devm_reset_control_array_get_shared(dev);
	if (IS_ERR(vpu_clk->resets)) {
		ret = PTR_ERR(vpu_clk->resets);
		dev_err(dev, "faied to get vpu reset controls\n");
	}

	ret = devm_clk_bulk_get(dev, vpu_clk->nr_clks, vpu_clk->clks);
	if (ret)
		dev_err(dev, "faied to get vpu clk controls\n");

	if (device_property_read_bool(dev, "starfive,vdec_noc_ctrl"))
		vpu_clk->noc_ctrl = true;

	return 0;
}

static vpu_clk_t *vpu_clk_get(struct platform_device *pdev)
{
	vpu_clk_t *vpu_clk;

	if (!pdev)
		return NULL;

	vpu_clk = devm_kzalloc(&pdev->dev, sizeof(*vpu_clk), GFP_KERNEL);
	if (!vpu_clk)
		return NULL;

	if (vpu_of_clk_get(pdev, vpu_clk))
		goto err_of_clk_get;

	return vpu_clk;

err_of_clk_get:
	devm_kfree(&pdev->dev, vpu_clk);
	return NULL;
}

static void vpu_clk_put(vpu_clk_t *clk)
{
	clk_bulk_put(clk->nr_clks, clk->clks);
}

static int vpu_clk_enable(vpu_clk_t *clk)
{
	int ret;

	ret = clk_bulk_prepare_enable(clk->nr_clks, clk->clks);
	if (ret)
		dev_err(clk->dev, "enable clk error.\n");

	DPRINTK("[VPUDRV] vpu_clk_enable\n");
	return ret;
}

static void vpu_clk_disable(vpu_clk_t *clk)
{
	clk_bulk_disable_unprepare(clk->nr_clks, clk->clks);
}
#endif
